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Announcements Homework #2 due now 50% credit if handed in next Tuesday Mid-term #1 in 1 week

Announcements Homework #2 due now 50% credit if handed in next Tuesday Mid-term #1 in 1 week Based on the first 10 lectures Multiple choice - bring pencils Lasts 1 hour and starts on time. The Moon. In this lecture…. Two types of terrain Highlands Maria Geologic features on the Moon

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Announcements Homework #2 due now 50% credit if handed in next Tuesday Mid-term #1 in 1 week

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  1. Announcements • Homework #2 due now • 50% credit if handed in next Tuesday • Mid-term #1 in 1 week • Based on the first 10 lectures • Multiple choice - bring pencils • Lasts 1 hour and starts on time

  2. The Moon

  3. In this lecture… • Two types of terrain • Highlands • Maria • Geologic features on the Moon • Craters and Volcanoes • Formation of the Moon • Giant impacts & Magma Oceans • The late heavy bombardment • Formation of the Maria • The recent years

  4. The moon is very close in comparison to other solar system objects • It’s 30 Earth diameters away • Mars (when closest) is ~6000 Earth diameters away • Other planets are even further

  5. 5th largest satellite in the solar system • Rock-like density • No atmosphere • So no wind action e.g. sand dune • No river channels or rainfall etc… • Critical body for planetary science • Much of what we do in studying solid planets started with work on the Moon • Simpler to understand than most planets

  6. Easy to get to – heavily visited by spacecraft • Late 1950s to early 1970s • Robotic craft from the USA & USSR • Ranger • Lunar Orbiter • Surveyor • Luna • Robotic Rovers (USSR) • Lunokhod • Manned missions (USA) • Apollo • 1990s • Clementine • Lunar Prospector

  7. More missions • Chandrayaan (India) • Chang’E (China) • Kaguya (Japan) • Smart 1 (Europe) • LRO (USA) – launching soon

  8. Two terrain types • Maria • Dark material – once thought to be seas • Terrae • Highlands • Light material – once thought to be the dry land

  9. No one knew what the far side of the Moon looked like until 1959 • Soviet Union launched Luna 3 • Far-side looks nothing like the near side • No Maria Near side Far side

  10. Geologic features on the Moon • The Moon is a really simple planet • Craters • Simple craters <18km diameter • Complex craters >18km diameter • Multi-ring basins • Pervasive ‘gardening’ from micrometeroites • Upper few km of the crust is fractured • Upper few meters has been turned into regolith Moltke – 1km Euler – 28km Orientale – 970km

  11. Volcanic features on the Mare • Lava flow fronts • Sinuous rilles (Collapsed lave tubes) • Vents and domes

  12. Mare basalt • Volcanic features on the Mare • Apollo samples • Tell us that the mare are sheets of volcanic rock • Highland Anorthosite

  13. Most of the lunar rocks look like this • Breccia • Fragments of rock fused together

  14. Maria • Overlapping volcanic flows and impacts • Samples show a volcanic composition • Basalt • Highlands • Just overlapping impacts • How did the Moon get this way?

  15. Formation of the Moon • Facts to consider • Moon depleted in iron & volatile substances • Like light elements and water • Oxygen isotope ratios similar to Earth • Moon doesn’t orbit in Earth’s equatorial plane • Possible theories (that didn’t work) • Earth and Moon co-accreted • Explains oxygen isotopes • Doesn’t explain iron and volatile depletion • Earth split into two pieces • Spinning so fast that it broke apart (fission) • …but the Moon doesn’t orbit in Earth’s equatorial plane • Capture of passing body • Earth captures an independently formed moon as it passes nearby • Pretty much a dynamical miracle • Doesn’t explain oxygen isotope similarity to Earth

  16. Current paradigm is Giant impact • Earth close to final size • Mars-sized impactor • Both bodies already differentiated • Both bodies formed at ~1 AU

  17. How does that explain the iron depletion • Bodies were already differentiated • All the iron sticks around in Earth’s core • Moon rock comes from Earth’s mantle – explains Oxygen isotope similarity • Red = iron • Yellow = rock From Robin Canup, SWRI Boulder

  18. What does that mean for the temperature of the two bodies? • Both very hot… • Magma oceans 100s of kilometers deep • Explains the Moon’s lack of volatile elements From Robin Canup, SWRI Boulder

  19. Core? • Accretion of lunar material into the Moon within a few years! • High-accretion rates mean surface is molten • Magma ocean probably a few hundred km thick • Apollo 11 returned highland fragments, first suggestion of Magma ocean • Idea since extended to other terrestrial planets Light minerals float ANORTHOSITE Dense minerals sink

  20. When the magma ocean freezes it seals in a lot of heat • Will become important later… • Crustal Thickness Asymmetry • Average crust 54-62km thick (45km at Apollo sites) • Far-side crust is much (about 15km) thicker • Crustal asymmetry is one of the central unanswered questions in lunar science

  21. Does the Moon have a core? • Remnant magnetism shows there was once a liquid core • Seismic experiments from Apollo – inconclusive • Another major unanswered question • Better seismic experiments would answer this • Apollo seismometers were all close together • Didn’t probe very deeply • Switched off in the 1970s to save $$

  22. Impact basins and the late heavy bombardment • Once the crust is solid – craters start to form • Some of these are still very large • 1000s of km across • Oldest rock fragments • From highlands ~4.5 Gyr ago • Spike in cratering rate • 4.0-3.8 Gyr ago • Late heavy bombardment • All the big basins we see today date from this period • All the inner planets suffered this bombardment Possible evidence for life– 3.8 Gyr ago Earliest certain evidence for life on Earth – 3.5 Gyr ago

  23. Bombardment movie played here • Research by LPL graduate student Dave Minton

  24. Big basins used to divide up the lunar timeline • Nectaris • Serenitatis • Imbrium • Orientale • etc…

  25. What does the Moon look like at that point? • Heavily cratered • All bright material • Orbits close to the Earth • Dotted with huge basins • The cratering rate dies off rapidly • Meanwhile…. • Things have been heating up in the subsurface 3.8 Gyr ago

  26. Formation of the Maria • Still need to add the dark patches • Huge amounts of volcanic material erupted onto the surface • Fills the existing big basins 3.8 Gyr ago 3.1 Gyr ago

  27. Maria start forming as the heavy bombardment era ends. • Maria crater density is much lower than the highlands • Regolith is shallower than highlands probably a few meters deep • Craters continue to accrue at a relatively slow rate until present day Mare formation period Known from Apollo samples Maria Cratering rate low after these lava flows form Highlands

  28. No volcanism on the far side • Thicker crust • Lava floods the pre-existing basins

  29. Mare material originates deep in the crust • Maria lava fill pre-existing depressions (impact basins) • Very similar to terrestrial basalt • Except that it is completely devolatilized • Darker color due to higher Fe content • Amounts are small… • Most Maria 1-2km thick • 5km in Imbrium, 0.6km in Orientale • Individual flows ~10-40m thick • VERY low viscosity • Flood basalts

  30. A few kilometers of volcanic rock is heavy… even on the Moon. • Subsidence of crust under basin • Compression in the center • Extension at edges Graben Wrinkle Ridges

  31. So how reliable is this? • Everything is based on Apollo samples • Some of these sites were later found to be geochemically ‘unusual’ • Lunar meteorites back up the Apollo results • Ejected from the Moon by impacts • Random sampling from around the Moon

  32. What happens after that? • Not much…. • More craters form over the last 3.1 Gyr, but a much lower rate. • The Moon has been pretty much dead for three billion years • Craters form bright rays that get darkened over time by micrometeorites • E.g. Tycho

  33. Lunar Timeline Pre-Nectarian 4.5 – 3.92 Ga • Giant impact between Earth and Mars sized body forms Moon • Magma ocean • Olivine rich rocks crystallize (rocks that sink) • Anorthosite highland formation (rocks that float) • Late Heavy bombardment • Homogenizes regolith up to 20 km • Large basins form • Impact rate declines significantly • Life forms on the Earth ? • Maria erupt onto surface • Mare material fills in preexisting basins • Lighter cratering continues • Recent craters still have bright rays Nectarian 3.92 – 3.85 Ga Imbrian 3.85 – 3.15 Ga Eratosthenian 3.15 – 1.0 Ga Copernican 1.0 – 0 Ga

  34. In this lecture… • Two types of terrain • Highlands • Maria • Geologic features on the Moon • Craters and Volcanoes • Formation of the Moon • Giant impacts & Magma Oceans • The late heavy bombardment • Formation of the Maria • The recent years Next: Craters • Reading • Chapter 10 to revise this lecture • Chapter 11-1,11-2 & 11-3 for next lecture

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